Reactions and energy absorption of trees subject to rockfall: a detailed assessment using a new experimental method

doi:10.1093/treephys/tpn030

Tree Physiology Advance Access originally published online on December 23, 2008
Tree Physiology 2009 29(3):345-359; doi:10.1093/treephys/tpn030

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Reactions and energy absorption of trees subject to rockfall: a detailed assessment using a new experimental method

Tor Lundström¹^,2^,3, Martin J. Jonsson¹, Axel Volkwein¹ and Markus Stoffel³

¹ WSL, Swiss Federal Institute for Snow and Avalanche Research SLF, CH-7260 Davos, Switzerland
² Corresponding author (t.lundstroem{at}slf.ch)
³ Laboratory of Dendrogeomorphology, University of Fribourg, 1700 Fribourg, Switzerland

Abstract

A new method for investigating the detailed reaction and theenergy absorption of trees during a rock impact was developedand applied to 15 subalpine Norway spruce (Picea abies L. Karst)trees. A wedge-shaped trolley, guided by prestressed steel wires,was mounted on a forested slope to simulate a falling rock.The trolley accelerates down the wires and hits a tree at apreselected stem height with variable energies. The tree displacementsand accelerations during the impact were recorded to determinereactions and energy absorption for the stem, root–soilsystem, crown and the entire tree. Trees absorbed the kineticenergy of the trolley rapidly by mobilizing strain and inertiaforces close to the impact location in the stem and the root–soilsystem. This energy was then gradually dissipated all over thetree through permanent deformations and damping. The stem assimilatedmore energy than the root–soil system. The tree’senergy absorption capacity was limited by stem-bending stressesat impact height, by shear stresses at the stem base and bylack of resistance of the root–soil anchorage. It waspositively and exponentially related to stem diameter at breastheight and negatively related to impact height. The field experimentenabled a physical description of how a tree reacts to a rockimpact and highlighted the most important and critical componentsof the tree for its energy absorption. Such descriptions shouldhelp make computer simulations of rock–forest interrelationsmore precise and thus improve management strategies to ensurethat forests can provide protection against rockfall.

Keywords: biomechanics, dynamics, energy balance, finite-element tree model, spatiotemporal analysis, stem deflection

Received August 15, 2008; Accepted October 20, 2008

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